Transient Response Tests
Advanced Transient Response Tests
For details on our transient response testing, please click here.
Ιn these tests, we monitor the HPT650M's response in several scenarios. First, a transient load (10A at +12V, 5A at 5V, 5A at 3.3V, and 0.5A at 5VSB) is applied for 200ms as the PSU works at 20 percent load. In the second scenario, it's hit by the same transient load while operating at 50 percent load.
In the next sets of tests, we increase the transient load on the major rails with a new configuration: 15A at +12V, 6A at 5V, 6A at 3.3V, and 0.5A at 5VSB. We also increase the load-changing repetition rate from 5 Hz (200ms) to 50 Hz (20ms). Again, this runs with the PSU operating at 20 and 50 percent load.
The last tests are even tougher. Although we keep the same loads, the load-changing repetition rate rises to 1 kHz (1ms).
In all of the tests, we use an oscilloscope to measure the voltage drops caused by the transient load. The voltages should remain within the ATX specification's regulation limits.
These tests are crucial because they simulate the transient loads a PSU is likely to handle (such as booting a RAID array or an instant 100 percent load of CPU/GPUs). We call these "Advanced Transient Response Tests," and they are designed to be very tough to master, especially for a PSU with a capacity of less than 500W.
We should note that the ATX spec requires for capacitive loading during the transient rests, but in our methodology we chose to apply the worst case scenario with no extra capacitance on the rails.
Advanced Transient Response at 20 Percent – 200ms
Advanced Transient Response at 20 Percent – 20ms
Advanced Transient Response at 20 Percent – 1ms
Advanced Transient Response at 50 Percent – 200ms
Advanced Transient Response at 50 Percent – 20ms
Advanced Transient Response at 50 Percent – 1ms
The +12V rail's result lands close to 1%, which reflects decent performance. It would, however, be better to see the HPT650M closer to its competition.
Voltage drops are notable on the minor rails, causing FSP's HPT650M to land in last place on our charts. The 3.3V rail's voltage falls way below 3.2V. In one of the tests, it even fails to stay within the ATX specification's tolerance.
Here are the oscilloscope screenshots we took during Advanced Transient Response Testing:
Transient Response At 20 Percent Load – 200ms
Transient Response At 20 Percent Load – 20ms
Transient Response At 20 Percent Load – 1ms
Transient Response At 50 Percent Load – 200ms
Transient Response At 50 Percent Load – 20ms
Transient Response At 50 Percent Load – 1ms
Turn-On Transient Tests
In the next set of tests, we measure the HPT650M’s response in simpler transient load scenarios—during its power-on phase.
For our first measurement, we turn the power supply off, dial in the maximum current the 5VSB rail can handle, and switch the PSU back on. In the second test, we set the +12V rail's maximum load and start the PSU while it is in standby mode. In the last test, with the PSU switched completely off, we dial in the +12V rail's maximum load before restoring power. The ATX specification states that recorded spikes on all rails should not exceed 10 percent of their nominal values (+10 percent for 12V is 13.2V, and 5.5V for 5V).
The 5VSB slope is perfect. Our results in the other two tests are satisfactory as well.
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